Kinetics and Mechanism of the Reaction of

686 NOTES

Inorganic Chemistry

and leaving the d,, orbital vacant. By this procedure, primary coordination sphere of chrornium(II1). The each nickel “receives” 16 electrons. reactions taking place are Within the metal atom cluster, the vacant pz orbital Cr(KH3)5C12++ Hg2++ H 2 0 = (A) of NiAand the dZ2orbitals (A E*) of the three NiB Cr(KH3)s(OH2)3+ + HgCl+ (1) atoms interact to produce three bonding MO’s, which Cr(P\rH3)sC12++ HgCl+ + H 2 0 = are filled by the six R electrons from the three carbonCr(XH8)j(OH2)3+ + HgC13 ( 2 ) carbon double bonds (A E) of the C4F6groups, which We have carried out studies on the kinetics and mechaare directed through the middle of the three faces. The nisms of these reactions. Special attention was directed metal cluster as a whole has two electrons less than the toward the hydrogen ion dependence of the rate and krypton configuration. toward a comparison of the rate a t which release of Thus the bonding in [ x - ( C F ~ ) ~ C ~ ] ~ Nis~unusual ~(CO)~ chloride ion is increased by mercury(I1) relative to in t h a t the R bonds from the T - ( C F ~ ) ~ C ligands * are dispontaneous aquation. A comparison is made of the rected not just to one metal atom as is customary, but to kinetic effect of those ligands on chromium(III), NHa a delocalized system of four metal atoms. It is well and H20,which remain unchanged. established that CO groups can bridge three metal Experimental Section atoms as in [ R - C ~ H ~ N ~ ] ~and ( C ORh6(CO)1617 )~~~ and The compound [Cr(SH3)5Cl]C1~ was prepared according to the recently it has been established1* t h a t the diphenylmethod of Schlessinger.3 The perchlorate salt was precipitated acetylene groups in the violet isomer of (CcHhC= from solutions of the chloride by slow addition of a solution of CC6HB)zFe3(C0)8 are located on opposite sides of a trilithium perchlorate or perchloric acid and cooling. The preangle of iron atoms. Species with structural features cipitate was washed with ice-cold water, ethanol, and ether and similar t o those proposed for [ T - ( C F ~ ) ~ C ~ ] ~ N ~ ~was ( Cdried O ) ~in air. Both the chloride and perchlorate salts were stored in opaque containers to prevent photochemical decommay be intermediates in the metal carbonyl catalyzed position which otherwise occurs. The compound [Cr(SHa)5trimerization of acetylenes. l9

+

+

Acknowledgments.-R. B. K. is indebted to Mr. M. B. Bisnette for experimental assistance. 11.I. B. thanks the Scientific Research Council for a predoctoral studentship and Mr. I. Paul for helpful discussions concerning the M O treatment. (16) E. 0. Fischer and C. Palm, B e y . , 91, 1726 (1958); A. A . Hock a n d 0 . S.Mills, “Advances in the Chemistry of the Coordination Compounds,” S. Kirschner, Ed., p 640. (17) E. R. Coi-el,. L. F. Dahl, a n d W. Beck, J . A m . Chem. Soc., 85, 1202 (1963). (18) R. P. Dodge a n d \-. Schomakei., J . O v g a ~ o m e l a l .Cizem., 3,274 (1965). (19) Hubel and C. Hoogzand, Be?,.,93, 103 (1960), and references cited therein.

w.

CONTRIBUTION F R O M

IXSTITUTE FOR L!ToMICRESEARCH DEPARTMENT O F CHEXISTRY, IOWA STATEUSIVERSITY,AMES, IOWA

THE

AND THE

Kinetics and Mechanism of the Reaction of Chloropentaamminechromium(III) Ion and Mercury(1I)l” BY JAMES H . ESPESSON ATD S u s ~ R. s HUB BARD'^ Recsived iVovember 8, 1965

The mechanisms of relatively few reactions of halochromium(II1) complexes with mercury(I1) ion have been reported. The aquation of Cr(NHa)&12+ appeared quite interesting, for the analogous reactions of Cr(OHz)6Cl2+ have been studied2 Mercury(I1) efficiently accelerates release of chloride ion from the (1) (a) Work performed in the Ames Laboratory of the U. S. Atomic Energy Commission. Contribution S o . 1823; (b) Undergraduate research participant, summer 1965. (2) J . H. Espenson a n d J. P. Birk, I?noI’g. Chevt., 4, 527 (1965).

O H ? ] C10& ( was prepared from the chloro complex by the method of Linhard and Bertho1d.l The visible and ultraviolet absorption spectra of these complexes agree with published Other reagents were prepared and analyzed as described previously. The spectrophotometric rate mcasuremcnts generally were made a t 3760 A on solutions in thermostated 10-cm silica cells; the procedure was similar to that previously employed.* The initial concentration of mercury(i1) was always a t least 20 times that of Cr( NH3)6C12T, and the reaction followed pseudofirst-order kinetics in every experiment. Rate constants were evaluated graphically, usually taking data to a t least 90% coinpletion, and generally were reproducible to within 2-5y0 average deviation. Spectral measurements on spent reaction solutions proved that the reaction product is Cr( SH3)sOH23+as written in eq 1 and 2 . The effects of ionic strength and anion concentration on similar reactions a t relatively high reactant concentrations have been considered in the earlier study of the related Cr( OH2)jC12+-Hg2+ reaction.2 As a consequence of these results, our rate measurements on both Hg2+and HgCl+ were carried out in an ionic medium which preserves both constant ionic strength and constant perchlorate ion concentration. X11 the data reported here refer to a medium of ionic strength 2.00 df, consisting of 0.50 J4 divalent ions (Ba2+, Hgz+, Cr(NHB)5Cl2+)arid 0.50 A. ! univalent ions (H+, Li+, HgCI+); perchlorate ion remained constant a t 1.50 M . Appropriate changes in [Ba2+]or [Li+], presumed to exert no specific effects other than electrolyte effects, compensated for changes in concentration of any other substance.

Results The rate data obey the equation

- d[Cr(NH3)jClZt]/dt

=

+

[Cr(;\H3)~C12+](K~[Hg2+] ki[HgCl-I)

(3)

(3) G. Schlessinger, Inorg. Syn.,6, 138 (1960). (4) M . Linhard a n d W. Berthold, 2 . A m i g . Allgent. Chem., 279, 173 (1955). We are grateful to Mr. R . R. Smardzewski for carrying o u t this preparation. (5) (a) M. A. Levine, T. P. Jones, W.E. Harris, a n d W. J. Wallace, J . Am. Chem. Soc., 83, 2453 (1961); (b) M. Linhard and M. Weigel, Z. A n o i g . Allgem. Chem., 266, 49 (1951); (c) R. Tsuchida, Bull. Chem. SOC.J u p a n , 13, 388 (1938); (d) R. Samuel, H. Hufiz, a n d X. Ahmad, Z. P h y s i k . Chem., B22, 431 (1933). (6) Our values for absorption maxima, . 4 (molar absorbance index, 31-1 cm-I), for Cr(NHa)sC12+ are 3760 (37.3) a n d 5120 (36.9). These values can be compared to 3750 (39) and 5120 (36),s* 3760 (43.6) and 5140 (38.O),Si’ 3750 (34.7) a n d 5120 (33.9),s0 3750 (31.7) and 5080 (40).Od

NOTES 687

Vol. 5, No. 4, April 1966 TABLE I

---

DETERMINATION OF THE ORDEROF

[Hg2+1,M b

Values of ka ( =

- [Hgz+]-l

THE

Hg2+-Cr( NH3)sClZf REACTION=

d In [Cr(N€Ia)aCl*+]/dt,Ad-' sec-1) a t various temperatures--25.0' 35.0'

15.0°

45.0'

0.0787, 0.0801 0.185, 0.190 0.456, 0.440 0.0825, 0.0856 0.198, 0.202 0.481, 0.499 0.0345, 0.0350 0.0812, 0.0834 0.199, 0.208 0.440, 0.513 0.0889, 0.0912 0.187, 0.197 0.0351, 0.0358 0.0890, 0.0895 0.237, 0.237 0.0905, 0.0928 0.0381, 0.0388 0.0879, 0.0928 0.0937 0.0867,O.0867 0.468 f 0.031 AV ko" 0.0361 f 0.0016 0.0871 rt 0.0045 0.214 f 0.020 0.0873 0.204 0.453 Calcd kod 0.0353 Ba(C104)Z added such that the total concentration of divalent cations M in most experiments. a [Cr(NHa)jC12+]o 2.5 X was 0.50 M ; also 0.50 F HC104. 0 Standard deviation given. d From the activation parameters presented in the text.

0.0500 0,100 0.150 0.200 0.250 0.300 0.350 0.400 0.500

-

1.0, and the fit is not appreciably better for any of these. The experimental results are summarized in Table 11, and the derived rate constants, using the extreme values of Q, 0.25 and 1.0, are given in Table 111. The value of kl in each experiment was computed from the relation

TABLE I1 PSEUDO-FIRST-ORDER RATEDATAFOR THE HgCl +-Cr( NH3)&12+REACTION ,

[ H g ( I I )I,

F

0.200 0.250 0.250 0.300

[CI -1, P

~

-

_

15.0'

l,, 2 , sec------

_

25.0'

7

35.0'

45.0'

0.300 210,231 91 39.0,41.5 15.4,16.2 0,300 116,120 4 9 . 5 , 5 0 . 0 2 2 . 5 , 2 3 . 0 10.4 0.400 197,216 82,88 49.5,fjO.O 1 4 . 9 , 1 5 . 0 ... ... 47 17.5 0.500 I

I n experiments on the effect of Hg2+,this species alone was present a t significant concentration. In evaluation of the rate constant for HgCl+, the KO term could not be suppressed entirely, however, and its calculated contribution was subtracted from the total. Table I summarizes the results on the Hg2+reaction of a series of kinetic experiments used to establish the reaction orders. The value of the second-order rate constant is independent of hydrogen ion concentration. In a series of experiments covering the range 0.05-0.50 M H + a t 0.50 M Hg2+, the value of ko was constant to within an average deviation of 3.0% a t 15.0', 2.5y0 a t 25.0') and 4.5% a t 35.0' (studied 0.10-0.50 A[ H + only) ; the variation was random, and no trends in ko with [ H + ] were apparent in these data.

RATECONSTANTS kl ( M - I -Composition[Hg(II)], F -

0.200 0.250 0.250 0.300

S E C - ~ ) FOR THE

---15.00----

TABLE I11 HgCl+-Cr(NH3)5C12fREACTION BASEDON DIFFERENTVALUESOF Q4

--

[Cl-], F

Q4 = 0.25

Q4 = 1.0

Q4 = 0.25

0.300 0.300 0.400 0.500

0.036 0.037 0.038

0.044 0.046 0.044

0.087 0.086 0.090

...

...

...

Interpretation of the kinetic data on the HgCl+ reaction is not without ambiguity since position of the equilibrium 2HgCl'

=

HgCln

+ Hg2+

(4)

is uncertain. Appreciable concentrations of Hg2f were present in solutions used in studying the reaction of HgClf. Various workers have studied the mercury(11) chloride equilibria PechanskP determined the value Q4 = [HgCI2][Hg2++l [HgC1+I2- = 0.40 a t 17.0' and 1.00 M ionic strength (NaC104). We have tried several values of Q in the range 0.25;'i8

with concentrations of the mercury species calculated from the formal concentrations using each particular value of Q4 and with the value of ko determined previously. These computations demonstrate t h a t these results are not very sensitive to the value of Q h chosen and that constancy of the values of kl calculated for different solutions cannot be used as an effective criterion for selecting a value of Q4. The interpretation of the data on the HgCl+ reaction assumes HgC12 does not possess significant catalytic effects toward Cr(NHI)6C12+. With 0.10 F HgClz (also 0.50 F Ba(C104)2and 0.50 F HCIOk), the pseudofirst-order rate constant for aquation of Cr (NH3)&12+ is -1.3 X sec-l a t 3 5 O , compared to 0.3 X sec-l for the spontaneous aquation in 1.0 F HCIOd a t this temperature.6a, Contributing also to the observed

25.00----04

----45.0°----

----35.0~--------.

1.0

0.104 0.108 0.108

...

Q4

0.25

0.195 0.178 0.188 0.15

Qd = 1.0

Q4 = 0.25

Qd = 1.0

0.229 0.220 0.216 0.17

0.51 0.40 0.52 0.43

0.61 0.48 0.63 0.49

rate is -1.7 X MHgCl+present in 0.10 F HgC12,' which provides 0.4 X loW4sec-l. An upper limit on the second-order rate constant for HgClz is then 0.6 X sec-l/0.1 M = 6 X M-l sec-l a t 35'. The HgClz present in the solutions used to study the (7) (a) L. G. Silleh, Acta Chem. Scand., 3, 539 (1940); (b) L. G . Silleh and G. Ingfeldt, Svrnsk. Kenz. T i d s k u . , 58, 61 (1946); (c) Y. Marcus, Acta Chem. Scand., 11, 599 (1957). (8) I). Pechanski, J . Chim. Phys., 5 0 , 640 (1953). The effect of medium upon this equilibrium has been discussed (ref 2). T h e value is relatively insensitive to temperature, with A H o = +1.0 kcal mole-1: P. Gallagher and E. L. King, J . A m . Chem. Soc., 82, 3510 (1960). (9) A. E. Ogard and H. Taube, ibid., 80, 1084 (1958).

6S8 NOTES

Inorganic Chemistry

HgCl + reaction does not contribute significantly to the aquation rate. The temperature dependences of the rate constants K O and kl were described in terms of the activation parameters AH* and AS* in the absolute rate theory equation, k = (kBT/h)e-AH*'RTeAS*iR. The values of bo and kl listed in Tables I and 111 mere fit to this equation Tvith a nonlinear least-squares programlo with the following results. For Hg2+,AH* = 14.9 =k 0.2 kcal mole-' and AS* = -13.4 =t 0.7 cal mole-1 deg-l with the indicated uncertainties representing standard deviations. I n the case of HgCl+, the calculation used values of k , based on different estimates for Q4 in the range 0.25-1.0. The activation parameters are not especially sensitive to the choice of Q 4 ; for the values 0.25, 0.38, and 1.0, AH* is 14.3 =k 0.6, 14.4 i 0.5, and 14.1 0.6 kcal mole-l, respectively. The corresponding values of A S * all lie within 2 eu of - 16 eu.

permitting a comparison of the activated complexes [ (NH3)Cr...C1...Hg(aqj4+]* and [ (NHz)BCr..*C1-** C ~ - ( a q ) ~ + ] *The . values of AS* for formation of these activated complexes from the component ions are - 13 and -27 eu,$respectively. TKOchanges affecting the first coordination spheres of the reactant complexes are impending in the transition state for the electron-exchange reaction: five ammonias are to be released by one chromium, and five water molecules are bound more strongly and more closely to the chromium nhich will become chromium(II1). The entropy of activation will reflect the extent to which the coordination spheres of the ions, in forming the transition state, are readjusted to equalize energies for electron transfer. The former change n-ould act to produce a more positive AS*, and the latter, a more negative value. Assuming these two factors provide the main contribution to AS* in the reaction of Cr(NH,),C12+ with Cr2+, beyond those factors common to each, one concludes the increasingly tight hold of water molecules by chromium Discussion is the more important. The 14 eu by which the AS* The observed lack of dependence of the rate of reacvalues of the two reactions differ does not appear untion I on hydrogen ion appears significant, especially reasonably large to be interpreted as the net effect of in view of the importance, in the analogous reaction of such changes Cr(OH2)&12+, of a rate law term k-1 [Cr(OHaj5C12+]. The reactions of Hg2+ with Cr(NH3)&12+ and Cr[ H g 2 + ] / [ H + in ] a region of [ H + ] where no appreciable (OHJ&Y2+, considering for the latter only the rate acid ionization of the reactants takes place. Two mechlaw term independent of hydrogen ion, proceed with anisms which are consistent with the kinetics for this remarkably similar specific rates, 0.087 and 0.048 pathway both involve a very slight extent of an acid sec-I a t 25.0'. The spontaneous aquation reactions, dissociation of one reactant, follon-ed by the ratehowever, differ in rateg2l1 by a factor of -70 a t the determining bimolecular reaction of its basic form with same temperature, again considering only the path the second reactant. The question of whether this independent of hydrogen ion in the case of Cr(OH,)jpath corresponds to reaction of Cr(OH%)A(OH)Cl+and C12-. I n the Hg2+-catalyzed aquation reactions, five Hg2+ or of Cr(OH2j5C12+and HgOH' necessarily reof the ligands on chromium(II1) exert only minor mains unsettled from the earlier n-ork. effects relative to their roles in spontaneous aquation. These results suggest rather strongly, but do not (11) 7 W Smaddle a n d E L King, I i z o i g Chem , 4 , 532 (1965) establish beyond question, that the reaction of the species Cr(OH2)4(0H)C1+with Hg2f rather than t h a t of HgOH+ with Cr(OH2jbC12+ is responsible for the rate law term inversely dependent upon hydrogen ion. The ion Cr(NH3)5C12+in the present study is a very COSTRIBUTIOX FROM THE HERCULES POWDER COMPANY, much weaker acid than is Cr(OH,)5C12+,whereas i t is WILMINGTON, DELAWARE19809 difficult to see how HgOH2+, comparably abundant in both studies, could discriminate drastically between the two acidic forms. It should be pointed out also Oxidation of Cuprous Chloride by t h a t analogous hydrogen ion dependences are observed Oxygen in Glacial Acetic Acid in the case of spontaneous aquation of chloroaquo and chloroammine complexes of chromium(II1) and cobaltBY PATRICK M. HESRY (111). Keceinred Derembei. 1, 1966 Although attempts have been made2! a t correlation of the rates and activation parameters of similar halideCuprous chloride has long been known to be oxidized transfer reactions with data on systems in which chloreadily by oxygen t o copper(I1) in aqueous solutions, ride ion transfer accompanies electron exchange, the but, because of the speeds of the reaction, attempts to earlier comparisons invariably involved rates or activadefine the kinetics have been u n s u ~ c e s s f u l . ~ -The ~ tion parameters for which complete experimental data oxidation of slurries of cuprous chloride in solvents were not available, and estimates based on analogy such as acetic acid is much slower than in water. This were employed. The present study provides data decrease in rate is presumably a t least partially due

*

( 1 0 ) This program is based on a report from t h e Los Alamos Scientific Laboratory, LA2367 plus addenda. We are grateful t o Drs. T. W. Newton and I